High Fidelity Restriction Endonucleases

ABSTRACT

Compositions and methods are provided for enzymes with altered properties that involve a systematic approach to mutagenesis and a screening assay that permits selection of the desired proteins. Embodiments of the method are particularly suited for modifying specific properties of restriction endonucleases such as star activity. The compositions includes restriction endonucleases with reduced star activity as defined by an overall fidelity index improvement factor.

CROSS REFERENCE

This application is a divisional of U.S. Ser. No. 13/736,406 filed Jan. 8, 2013 which is a divisional of U.S. Ser. No. 12/172,963, filed Jul. 14, 2008 now U.S. Pat. No. 8,372,619, which claims priority from U.S. provisional application Ser. No. 60/959,203 filed Jul. 12, 2007, herein incorporated by reference.

BACKGROUND

Restriction endonucleases are enzymes that cleave double-stranded DNAs in a sequence-specific manner (Roberts, R. J., Proc Natl Acad Sci USA, 102:5905-5908 (2005); Roberts, et al., Nucleic Acids Res, 31:1805-1812 (2003); Roberts, et al., Nucleic Acids Res, 33:D230-232 (2005); Alves, et al., Restriction Endonucleases, “Protein Engineering of Restriction Enzymes,” ed. Pingoud, Springer-Verlag Berlin Heidelberg, New York, 393-407 (2004)). They are ubiquitously present among prokaryotic organisms (Raleigh, et al., Bacterial Genomes Physical Structure and Analysis, Ch.8, eds. De Bruijin, et al., Chapman & Hall, New York, 78-92 (1998)), in which they form part of restriction-modification systems, which mainly consist of an endonuclease and a methyltransferase. The cognate methyltransferase methylates the same specific sequence that its paired endonuclease recognizes and renders the modified DNA resistant to cleavage by the endonuclease so that the host DNA can be properly protected. However, when there is an invasion of foreign DNA, in particular bacteriophage DNA, the foreign DNA will be degraded before it can be completely methylated. The major biological function of the restriction-modification system is to protect the host from bacteriophage infection (Arber, Science, 205:361-365 (1979)). Other functions have also been suggested, such as involvement in recombination and transposition (Carlson, et al., Mol Microbiol, 27:671-676 (1998); Heitman, Genet Eng (NY), 15:57-108 (1993); McKane, et al., Genetics, 139:35-43 (1995)).

The specificity of the approximately 3,000 known restriction endonucleases for their greater than 250 different target sequences could be considered their most interesting characteristic. After the discovery of the sequence-specific nature of the first restriction endonuclease (Danna, et al., Proc Natl Acad Sci USA, 68:2913-2917 (1971); Kelly, et al., J Mol Biol, 51:393-409 (1970)), it did not take long for scientists to find that certain restriction endonucleases cleave sequences which are similar but not identical to their defined recognition sequences under non-optimal conditions (Polisky, et al., Proc Natl Acad Sci USA, 72:3310-3314 (1975); Nasri, et al., Nucleic Acids Res, 14:811-821 (1986)). This relaxed specificity is referred to as star activity of the restriction endonuclease. It has been suggested that water-mediated interactions between the restriction endonuclease and DNA are the key differences between specific complexes and star complexes (Robinson, et al., J Mol Biol, 234:302-306 (1993); Robinson, et al., Proc Natl Acad Sci USA, 92:3444-3448 (1995), Sidorova, et al., Biophys J, 87:2564-2576 (2004)).

Star activity is a problem in molecular biology reactions. Star activity introduces undesirable cuts in a cloning vector or other DNA. In cases such as forensic applications, where a certain DNA substrate needs to be cleaved by a restriction endonuclease to generate a unique fingerprint, star activity will alter a cleavage pattern profile, thereby complicating analysis. Avoiding star activity is also critical in applications such as strand displacement amplification (Walker, et al., Proc Natl Acad Sci USA, 89:392-396 (1992)) and serial analysis of gene expression (Velculescu, et al., Science, 270:484-487 (1995)).

SUMMARY

In an embodiment of the invention, a composition is provided that includes a restriction endonuclease having at least one artificially introduced mutation and an overall fidelity index (FI) improvement factor of at least two, the restriction endonuclease being capable of cleaving a substrate with at least a similar cleavage activity to that of the restriction endonuclease absent the artificially introduced mutation in a predetermined buffer, the artificially introduced mutation being the product of at least one of a targeted mutation, saturation mutagenesis, or a mutation introduced through a PCR amplification procedure.

In a further embodiment of the invention, at least one of the artificially introduced mutations is a targeted mutation resulting from replacement of a naturally occurring residue with an oppositely charged residue. An Alanine or a Phenylalanine may replace the naturally occurring residue at the target site.

In a further embodiment of the invention, a composition of the type described above includes a restriction enzyme absent the artificially introduced mutation selected from the group consisting of: BamHI, EcoRI, ScaI, SalI, SphI, PstI, NcoI, NheI, SspI, NotI, SacI, PvuII, MfeI, HindIII, SbfI, EagI, EcoRV, AvrII, BstXI, PciI, HpaI, AgeI, BsmBI, BspQI, SapI, KpnI and BsaI.

Further embodiments of the invention include compositions listed in Table 4.

In a further embodiment of the invention, a DNA encoding any of the enzymes listed in Table 4 is provided, a vector comprising the DNA and a host cell for expressing the protein from the vector.

In an embodiment of the invention, a method is provided having the steps of (a) identifying which amino acid residues in an amino acid sequence of a restriction endonuclease having star activity are charged amino acids; (b) mutating one or more codons encoding one or more of the charged residues in a gene sequence encoding the restriction endonuclease; (c) generating a library of gene sequences having one or more different codon mutations in different charged residues; (d) obtaining a set of proteins expressed by the mutated gene sequences; and (e) determining an FI in a predetermined buffer and a cleavage activity for each expressed protein.

An embodiment of the method includes the step of determining an overall FI improvement factor for proteins belonging to the set of proteins in a defined set of buffers where for example, the set of buffers contains NEB1, NEB2, NEB3 and NEB4 buffers.

An embodiment of the method includes the steps described above and additionally mutating codons encoding hydroxylated amino acids or amide amino acids in a same or subsequent step to that of mutating codons for the charged amino acids.

In an embodiment of the invention described above, the codons are mutated to an Alanine except for Tyrosine which is mutated to a Phenylalanine.

In a further embodiment, the overall FI improvement factor is improved using saturation mutagenesis of one or more of the mutated codon.

BRIEF DESCRIPTION OF THE DRAWINGS

In each of the reactions described in FIGS. 1-4A-B, the reaction mixture contains a volume of 3 μl unless otherwise specified of a buffer from New England Biolabs, Inc. (NEB), Ipswich, Mass., (see Table 1 and NEB catalog), 3 μl unless otherwise specified of a specified restriction endonuclease in a diluent from NEB, Ipswich, Mass. (See Table 1 and NEB catalog) as well as variable volumes of specified substrate (containing 0.6 μg) substrate and a volume of water to bring the reaction mixture to a total of 30 μl. Reactions were conducted at 37° C. for an incubation time of 1 hour. The results are analyzed on a 0.8% agarose gel. Where the overall volume of the reaction mix, amount of substrate, temperature of the reaction or incubation time varies from above, values are provided in the description of the figures.

The theoretical digestion pattern is provided on the right side of the gel for FIGS. 1 and 4A-B. Those substrates with only one restriction endonuclease site should be digested into one linear band from supercoiled form.

FIG. 1 shows the determination of the FI for wild type (WT) ScaI by digesting 1.2 μl lambda DNA substrate (0.6 μg) with a two-fold serial dilution using diluent A of a preparation of WT ScaI (1,200 U) in NEB3 buffer and examining the digestion products on an agarose gel. The highest concentration of a restriction endonuclease with no star activity is shown with a solid arrow; and the minimum concentration giving rise to complete digestion of substrate is shown with a hollow arrow.

For FIGS. 2A-4B:

The * symbol indicates the lane to its left that contains the lowest concentration of enzyme for which star activity is observed.

The # symbol refers to the lane showing incomplete cleavage, which is adjacent to and to the right side of the lane containing a concentration of enzyme sufficient for complete cleavage of the substrate.

“U” denotes units of enzyme.

FIGS. 2A-D show a comparison of WT EcoRI and EcoRI(K62A) in NEB1-4 buffers in a 3-fold serial dilution using NEB diluent C. The reaction mixture contained 2 μl lambda DNA substrate (1 μg) in NEB1-4 buffers.

FIG. 2A shows the cleavage results following 2-fold serial dilution, 120 U WT EcoRI and 240 U of EcoRI (K62A) in NEB2 buffer.

FIG. 2B shows the cleavage results following 2-fold serial dilution, 120 U WT EcoRI and 240 U of EcoRI (K62A) in NEB4 buffer.

FIG. 2C shows the cleavage results following 2-fold serial dilution, 60 U WT EcoRI and 120 U of EcoRI (K62A) in NEB1 buffer.

FIG. 2D shows the cleavage results following 2-fold serial dilution, 120 U WT EcoRI and 60 U of EcoRI (K62A) in NEB3 buffer.

FIGS. 3A-C show the cleavage results with 2 different EcoRI mutants and WT EcoRI. The digestion of 100,000 U of enzyme and a 10-fold serial dilution thereof in diluent C over 10 hours using 0.6 μl of Litmus28 substrate in various buffers is shown. There is only one EcoRI cleavage site in Litmus28 substrate.

FIG. 3A: EcoRI mutant K62E in NEB4 buffer.

FIG. 3B: EcoRI mutant K62A in NEB4 buffer.

FIG. 3C: WT EcoRI in EcoRI buffer (see NEB catalog 2007-8).

FIGS. 4A-B shows a comparison of EcoRI-HF and WT EcoRI in NEB4 buffer. The reaction utilized 1.2 μl lambda DNA substrate in a 2-fold serial dilution using diluent C.

FIG. 4A: WT EcoRI with a starting concentration of 19,200 U reveals a FI=4 in NEB4 buffer.

FIG. 4B: EcoRI-HF with a starting concentration of 38,400 U reveals a FI=16,000 in NEB4 buffer.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Embodiments of the invention provide a general method for selecting for restriction endonucleases with desired characteristics. The general method relies on a suitable assay for determining whether the desired restriction endonuclease has been created. In particular an embodiment of the general method provides a systematic screening method with a set of steps. This method has been deduced by performing many hundreds of reactions using many restriction endonucleases. The example provided herein relates to identifying a restriction endonuclease with reduced star activity but with cleavage activity that is at least similar to the WT restriction endonuclease. However, it is expected that the same methodology can be applied successfully to modifying other properties of the restriction endonucleases relating, for example, to improved cleavage activity in desired buffers, thermostability, rate of reaction in defined conditions, etc.

As discussed above, an end point of interest is to transform restriction endonucleases with star activity into high fidelity restriction endonucleases with significantly reduced star activity. Star activity refers to promiscuity in cleavage specificity by individual restriction endonucleases. The terms “reduction in star activity” and “increase in fidelity” are used interchangeably here. Although restriction endonucleases are characterized by their property of cleaving DNA at specific sequences, some restriction endonucleases additionally cleave DNA inefficiently at secondary sites in the DNA. This secondary cleavage may occur consistently or may arise only under certain conditions such as any of: increased concentrations, certain buffers, temperature, substrate type, storage, and incubation time.

It is generally acknowledged that little is known about the complex environment generated by the hundreds of amino acids that constitute a protein and determine specificity. One approach in the prior art has been to utilize crystallography to identify contact points between an enzyme and its substrate. Nonetheless, crystallography has limitations with respect to freezing a structure in time in an unnatural chemical environment.

The rules that determine the contribution of amino acids at any site in the protein and the role played by the structure of the substrate molecule has proved elusive using existing analytical techniques. For example, it is shown here that mutating an amino acid in a restriction endonuclease can cause all or partial loss of activity.

In this context, no structural explanation has been put forward to explain why star activity could increase with high glycerol concentration (>5% v/v), high enzyme to DNA ratio (usually >100 units of enzyme per μg of DNA), low ionic strength (<25 mM salt), high pH (>8.0), presence of organic solvent (such as DMSO, ethanol), and substitution of Mg′ with other divalent cations (Mn²⁺, Co²⁺). It was here recognized that because of the diversity of factors affecting star activity, it would be necessary to conduct comparisons of WT and mutant star activity under the same reaction conditions and in the same predetermined buffer and to develop a standard reaction condition in which any high fidelity enzyme must be capable of showing the described characteristics even if these characteristics were also observed in other reaction conditions.

Present embodiments of the invention are directed to generating modified restriction endonucleases with specific improved properties, namely enhanced cleavage fidelity without significant reduction in overall cleavage activity or significant loss of yield from the host cells that make the protein. The methods that have been developed here for finding mutants with improved properties have resulted from exhaustive experimentation and the properties of the resultant enzymes have been defined in the context of specified conditions. The methods described herein may be used for altering the enzymatic properties of any restriction endonuclease under predetermined conditions, but are not limited to the specific defined conditions.

Restriction Steps Used to Generate a High Fidelity Restriction Endonuclease Endonuclease BamHI Comparison of isoschizomer Targeted 22 residues to mutate to Ala. 14 mutants obtained, 3 had improved fidelity Saturation mutagenesis on 2 residues-K30 and E86 Recovered E86P as preferred mutant with greatest reduced star activity in selected buffers. Added mutations to E86P. Second round of mutation (Arg, Lys, His, Asp, Glu, Ser, Thr) to Ala and Tyr to Phe. Selected E167 and Y165 for saturation mutagenesis and selected E167T and Y165F. E163A/E167T was selected as preferred high fidelity mutant (BamHI-HF). EcoRI Comparison of isoschizomer (Ex. 1) Targeted 42 charged residues to mutate to Ala. No high fidelity mutants Second round of mutation: Target additional 32 charged residues to mutate to Ala: Identified K62A. Saturation mutagenesis on K62A. EcoRI(K62E) was selected as a preferred high fidelity mutant (EcoRI-HF). ScaI Comparison of isoschizomers. Targeted 58 charged residues to mutate to Ala. Identify 4 mutants Preferred mutant of 4 is (H193A/S201F). This is selected as a preferred high fidelity mutant (ScaI-HF) SalI Target 86 charged residues and mutate to Ala. SalI (R107A) was preferentially selected as a preferred high fidelity mutant (SalI- HF). SphI Target 71 charged residues and mutate to Ala. SphI (K100A) was preferentially selected as a preferred high fidelity mutant (SphI- HF) PstI Target 92 charged amino acids and mutate to Ala. PstI (D91A) was preferentially selected as a preferred high fidelity mutant (PstI-HF) NcoI Target 66 charged residues and mutate to Ala. NcoI (A2T/R31A) was preferentially selected as a preferred high fidelity mutant (NcoI-HF). NheI Target 92 charged residues and mutate to Ala. NheI (E77A) was preferentially selected as a preferred high fidelity mutant (NheI- HF) SspI Target 81 charged residues and mutate to Ala. No preferential mutants obtained. Target 95 residues to additional charged residues and hydroxylated residues to Ala except Tyr. Tyr mutated to Phe. SspI (Y98F) was preferentially selected as a preferred high fidelity mutant (SspI-HF) NotI Target 97 charged residues and mutate to Ala. K150A was preferentially selected as a preferred high fidelity mutant (NotIHF) SacI Target 101 charged residues and mutate to Ala. SacI (Q117H/R200A) was preferentially selected as a preferred high fidelity mutant (SacI-HF) where Q117H was a carry over mutation from template with no affect on activity PvuII Target 47 charged residues and mutate to Ala. No preferred mutants obtained Target 19 hydroxylated residues - Ser/Thr and Tyr. Select T46A for further improvement Saturation mutagenesis results in a preferred mutant T46G, T46H, T46K, T46Y. PvuII(T46G) was preferentially selected as a preferred high fidelity mutant (PvuII-HF) MfeI Target 60 charged residues and mutate to Ala. No preferred mutants obtained Target 26 hydroxylated residues and mutate to Ala except for Tyr which was changed to Phe. Target 38 residues (Cys, Phe, Met, Asn, Gln, Trp) and mutate to Ala Identify Mfe (Q13A/F35Y) as a preferred high fidelity mutant (MfeI-HF) where F35Y is carried from the template HindIII Target 88 charged residues and mutate to Ala. No preferred mutants obtained Target 103 residues (Cys Met Asn, Gln, Ser Thr Trp) and mutate to Ala and Tyr changed to Phe. Identify HindIII (K198A) as a preferred high fidelity mutant (HindIII-HF) SbfI Target 78 charged residues mutated to Ala Target 41 residues (Ser Thr) mutated to Ala/Tyr to Phe Target 55 residues of Cys, Phe, Met Asn, Gln, Trp to Ala SbfI (K251A) was selected as a preferred high fidelity mutant (SbfI-HF) EagI Target 152 residues (Asp, Glu, His, Lys, Arg, Ser, thr, Asn, and Gln changed to Ala and Tyr changed to Phe). EagI H43A was selected as a preferred high fidelity mutant (EagIHF) EcoRV Target 162 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) EcoRV (D19A/E27A) was selected as a preferred high fidelity mutant (EcoRV-HF) AvrII Target 210 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) AvrII (Y104F) was selected as a preferred high fidelity mutant (AvrII-HF) BstXI Target 237 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) BstXI (N65A) was selected as a preferred high fidelity mutant (BstXI-HF) PciI Target 151 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) PciI (E78A/S133A) was selected as a preferred high fidelity mutant. (PciI-HF) This was spontaneous and not one of the 151 separate mutations HpaI Target 156 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) HpaI (E56A) was selected as a preferred high fidelity mutant (HpaI-HF) AgeI Target 149 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) AgeI (R139A) was selected as a preferred high fidelity mutant (AgeI-HF) BsmBI Target 358 residues (Cys, Asp, Glu, Phe, his, Lys, Met, Asn, Gln, Arg, Ser, Thr, to Ala and Trp to Phe) BsmBI(N185Y/R232A) was selected as a preferred high fidelity mutant (BsmBI (HF) BspQI Target 122 residues (Arg, Lys, His, Glu, Asp, Gln, Asn, Cys) Replace R at position 279 with Phe, Pro, Tyr, Glu, Asp or Leu. Preferred mutations were R388F and K279P. Created a double mutant BspQI(K279P/R388F) as preferred high fidelity mutant (BspQI-HF) SapI Find K273 and R380 in SapI corresponding to R388 and K279 in BspQI. SapI (K273P/R380F) was selected as a preferred high fidelity mutant (SapI-HF) KpnI Target all residues (Asp, Glu, Arg, Lys, His, Ser, Thr, Tyr, Asn, Gln, Phe, Trp, Cys, Met) to Ala. More mutation was done on site D16 and D148. A combined D16N/E132A/D148E was selected as a preferred high fidelity mutant (KpnI-HF). BsaI Find 11 amino acids corresponding to the site in BsmBI. BsaI (Y231F) was selected as a preferred high fidelity mutant (BsaI-HF).

The method follows from the realization that amino acids responsible for cognate activity and star activity are different. The engineering of high fidelity restriction endonucleases described herein demonstrates that cognate activity and star activity can be separated and there are different critical amino acid residues that affect these different activities. The locations of amino acids that are here found to affect star activity are not necessarily found within the active site of the protein. The cleavage properties of any restriction endonuclease has been determined here for the first time by developing a criterion of success in the form of determining a FI (see also Wei, et al. Nucleic Acid Res., 36, 9, e50 (2008)) and an overall fidelity index improvement factor.

An “overall fidelity index improvement factor” refers to the highest FI for a mutant with maximum cleavage activity divided by the highest FI of the corresponding WT endonuclease with maximum cleavage activity within a selected set of buffers. The selected set may be of any size greater than one but practically will contain less than 10 different buffers and more preferably contains 4 buffers. The set may also include less than 4 buffers. The overall FI improvement factor of at least two should preferably be applicable for any mutant restriction endonuclease in the claimed invention additionally but not exclusively to the set of buffers consisting of NEB1, NEB2, NEB3 and NEB4.

A “similar cleavage activity” can be measured by reacting the same amount of enzyme with the same amount and type of substrate under the same conditions and visually comparing the cleavage profiles on a gel after electrophoresis such that the amount of cleavage product appears to be the same within a standard margin of error and wherein the quantitative similarity is more than 10%.

“Artificial” refers to “man-made”.

“Standard conditions” refers to an overall FI improvement factor calculated from results obtained in NEB1-4 buffers.

The general method described herein has been exemplified with 27 restriction endonucleases: AgeI, AvrII, BamHI, BsaI, BsmBI, BspQI, BstXI, EagI, EcoRI, EcoRV, HindIII, HpaI, KpnI, MfeI, NcoI, NheI, NotI, PciI, PstI, PvuII, SacI, SalI, SapI, SbfI, ScaI, SphI and SspI restriction endonucleases. However, as mentioned above, the method is expected to be effective for the engineering of any restriction endonuclease that has significant star activity.

Embodiments of the method utilize a general approach to create mutant restriction endonucleases with reduced star activity. For certain enzymes, it has proven useful to mutate charged residues that are determined to be conserved between two isoschizomers. In general, however, the method involves a first step of identifying all the charged and polar residues in a protein sequence for the endonuclease. For example, charged amino acids and polar residues include the acidic residues Glu and Asp, the basic residues His, Lys and Arg, the amide residues Asn and Gln, the aromatic residues Phe, Tyr and Trp and the nucleophilic residue Cys. Individual residues are targeted and mutated to an Ala and the products of these targeted mutations are screened for the desired properties of increased fidelity. If none of the mutants obtained provide a satisfactory result, the next step is to target mutations to all the hydroxylated amino acids, namely, Ser, Thr and Tyr, the preferred mutation being Ser and Thr to Ala and Tyr to Phe. It is also possible to target mutations to both classes of residues at one time. The mutation to Ala may be substituted by mutations to Val, Leu or Ile.

After these analyses, if one or more of the preferred mutants generated in the above steps still have substandard performance under the selected tests, these mutants can be selected and mutated again to each of the additional possible 18 amino acids. This is called saturation mutagenesis. Saturation mutagenesis provided the preferred high fidelity mutants for EcoRI, BamHI in part and PvuII. Depending on the results of saturation mutagenesis, the next step would be to introduce additional mutations either targeted or random or both into the restriction endonuclease. SacI-HF includes a random mutation generated fortuitously during inverse PCR. PciI-HF resulted from a random mutation and not from targeted mutations. BspQI-HF contains two mutations that were found to act synergistically in enhancing fidelity.

The use of various methods of targeted mutagenesis such as inverse PCR may involve the introduction of non-target mutations at secondary sites in the protein. These secondary mutations may fortuitously provide the desired properties. It is desirable to examine those mutated enzymes with multiple mutations to establish whether all the mutations are required for the observed effect. Q117H in the double mutant had no effect on activity.

In some cases, a mutation may provide an additional advantage other than improved fidelity.

The high fidelity/reduced star activity properties of the mutants provided in the Examples were selected according to their function in a set of standard buffers. Other mutations may be preferable if different buffer compositions were selected. However, the same methodology for finding mutants would apply. Table 4 lists mutations which apply to each restriction endonuclease and provide an overall FI improvement factor in the standard buffer.

The engineering of the high fidelity restriction endonucleases to provide an overall FI improvement factor of at least 2 involves one or more of the following steps:

1. Assessment of the Star Activity of the WT Restriction Endonuclease

In an embodiment of the invention, the extent of star activity of a restriction endonuclease is tested by means of the following protocol: the endonuclease activity is determined for an appropriate substrate using a high initial concentration of a stock endonuclease and serial dilutions thereof (for example, two-fold or three-fold dilutions). The initial concentration of restriction endonuclease is not important as long as it is sufficient to permit an observation of star activity in at least one concentration such that on dilution, the star activity is no longer detected.

An appropriate substrate contains nucleotide sequences that are cleaved by cognate endonuclease activity and where star activity can be observed. This substrate may be the vector containing the gene for the restriction endonuclease or a second DNA substrate. Examples of substrates used in Table 2 are pBC4, pXba, T7, lambda, and pBR322.

The concentration of stock restriction endonuclease is initially selected so that the star activity can be readily recognized and assayed in WT and mutated restriction endonucleases. Appropriate dilution buffers such as NEB diluent A, B or C is selected for performing the serial dilutions according to guidelines in the 2007-08 NEB catalog. The serially diluted restriction endonuclease is reacted with a predetermined concentration of the appropriate substrate in a total reaction volume that is determined by the size of the reaction vessel. For example, it is convenient to perform multiple reactions in microtiter plates where a 30 μl reaction mixture is an appropriate volume for each well. Hence, the examples generally utilize 0.6 μg of substrate in 30 μl, which is equivalent to 1 μg of substrate in 50 μl. The amount of substrate in the reaction mixture is not critical, but it is preferred that it be constant between reactions. The cleavage reaction occurs at a predetermined temperature (for example 25° C., 30° C., 37° C., 50° C., 55° C. or 65° C.) for a standard time such as one hour. The cleavage products can be determined by any standard technique, for example, by 0.8% agarose gel electrophoresis to determine the fidelity indices as defined above.

Not all restriction endonucleases have significant star activity as determined from their FI. However, if an endonuclease has a highest FI of no more than about 250 and a lowest FI of less than 100, the restriction endonuclease is classified as having significant star activity. Such endonucleases are selected as a target of enzyme engineering to increase fidelity for a single substrate. In some cases, the restriction endonucleases with both FI over about 500 and FI less than about 100 are also engineered for better cleavage activity.

Table 2 below lists the FI of some engineered restriction endonucleases before engineering. All samples were analyzed on 0.8% agarose gel.

TABLE 2 Diluent Temp Enzyme (NEB)*** Substrate* ° C. FI-1** FI-2** FI-3** FI-4** AgeI C pXba 37 16 (1) 8 (½) 64 (⅛) 8 (½) AwrII B T7 37 64 (1) 8 (1) 32 (¼) 32 (1) BamHI A λ 37 4 (½) 4 (1) 32 (1) 4 (½) BsaI B pBC4 50 8 (¼) 120 (1) 16 (¼) 32 (1) BsmBI B λ 55 1 (⅛) 8 (½) 120 (1) 4 (¼) BspQI B λ 50 2 (⅛) 16 (1) 32 (1) 4 (½) BstXI B λ 55 2 (½) 2 (½) 2 (⅛) 4 (1) EagI B pXba 37 4 (¼) 8 (½) 250 (1) 16 (1) EcoRI C λ 37 250 (½) 4 (1) 250 (1) 4 (1) EcoRV A pXba 37 32 ( 1/16) 120 (½) 1000 (1) 64 (¼) HindIII B λ 37 32 (¼) 250 (1) 4000 (¼) 32 (½) HpaI A λ 37 32 ( 1/16) 1 (¼) 2 (⅛) 16 (1) KpnI A pXba 37 16 (1) 16 (¼) 8 ( 1/16) 4 (½) MfeI A λ 37 32 (1) 16 (⅛) 8 ( 1/16) 32 (1) NcoI A λ 37 120 (1) 32 (1) 120 (¼) 32 (1) NheI C pXba 37 32 (1) 120 (¼) 120 (⅛) 32 (1) NotI C pXba 37 ≧32000 ( 1/16) 64 (1) 500 (1) 32 (¼) PciI A pXba 37 2000 (½) 16 (¼) 120 (1) 8 (⅛) PstI C λ 37 64 (1) 32 (1) 120 (1) 8 (½) PvuII A pBR322 37 250 (1) 16 (¼) 8 ( 1/32) ¼ (1) SacI A pXba 37 120 (1) 120 (½) 120 ( 1/32) 32 (½) SalI A λ (H3) 37 8 ( 1/500) 1 ( 1/16) 32 (1) 1 ( 1/120) SapI C λ 37 16 (¼) 64 (½) 32 (¼) 16 (1) SbfI A λ 37 32 (1) 8 (¼) 8 ( 1/16) 8 (½) ScaI A λ 37 1/16 ( 1/32) ⅛ (1) 4 (½) 1/64 ( 1/16) SphI B λ 37 64 (1) 32 (1) 64 (¼) 16 (½) SspI C λ 37 64 (1) 16 (1) 32 (¼) 16 (1) *Substrate: λ is lambda phage DNA; λ (H3) is HindIII-digested lambda phage DNA; pXba is pUC19 with XbaI-digested fragment of Adeno Virus; pBC4: a shorter version of pXba; T7: T7 DNA **FI-1 to FI-4: fidelity index of the enzyme in NEBuffer 1, 2, 3 and 4. The number in parenthesis is a value for relative cleavage activity of the mutant restriction endonuclease in a specified buffer in a set of buffers compared with the “best” cleavage activity of the same mutant restriction endonuclease in any of the buffers in the set of buffers. The compositions of NEB buffers follow: NEB1: 10 mM Bis Tris Propane-HCl, 10 mM MgCl₂, 1 mM dithiothreitol (pH 7.0 at 25° C.); NEB2: 50 mM NaCl, 10 mM Tris-HCl, 10 mM MgCl₂, 1 mM dithiothreitol (pH 7.9 at 25° C.); NEB3: 100 mM NaCl, 50 mM Tris-HCl, 10 mM MgCl₂, 1 mM dithiothreitol (pH 7.9 at 25° C.); NEB4: 50 mM potassium acetate, 20 mM Tris-acetate, 10 mM magnesium acetate, 1 mM dithiothreitol (pH 7.9 at 25° C.). ***The compositions of NEB diluents follow. (Using diluents in the dilution instead of water will keep the glycerol concentration in the reaction as a constant.) Diluent A: 50 mM KCl, 10 mM Tris-HCl, 0.1 mM EDTA, 1 mM dithiothreitol, 200 mg/ml BSA. 50% glycerol (pH 7.4 at 25° C.); Diluent B: 300 mM NaCl, 10 mM Tris-HCl, 0.1 mM EDTA, 1 mM dithiothreitol, 500 mg/ml BSA, 50% glycerol (pH 7.4 at 25° C.); Diluent C: 250 mM NaCl, 10 mM Tris-HCl, 0.1 mM EDTA, 1 mM dithiothreitol, 0.15% Triton X-100, 200 mg/ml BSA, 50% glycerol (pH 7.4 at 25° C.).

2. Construction of High Expression Host Cell Strains

It is convenient if a host cell is capable of over-expressing the mutant restriction endonuclease for which reduced star activity is sought. If the restriction enzyme is highly expressed in E. coli, the star activity can be readily detected in the crude extract, which simplifies the screening for the high fidelity restriction endonuclease. However, the mutated restriction endonuclease can be expressed in any host cell providing that the host cell is protected in some way from toxicity arising from enzyme cleavage. This might include: the presence of a methylase; production in a compartment of the cell which provides a barrier to access to the genome (such as an inclusion body or the periplasm); in vitro synthesis; production in an emulsion (see U.S. patent application Ser. No. 12/035,872) absence of cleavage sites in the host genome; manufacture of the enzyme in component parts subject to intein mediated ligation (see U.S. Pat. No. 6,849,428), etc.

Over-expression of the mutated restriction endonucleases for purposes of production can be achieved using standard techniques of cloning, for example, use of an E. coli host, insertion of the endonuclease into a pUC19-derived expression vector, which is a high copy, and use of a relatively small plasmid that is capable of constant expression of recombinant protein. The vector may preferably contain a suitable promoter such as the lac promoter and a multicopy insertion site placed adjacent to the promoter. Alternatively, a promoter can be selected that requires IPTG induction of gene expression. If the activity in the crude extract is not sufficient, a column purification step for the restriction endonuclease in crude extract may be performed.

3. Mutagenesis of Restriction Endonuclease

DNA encoding each charged or polar group in the restriction endonuclease may be individually targeted and the mutated DNA cloned and prepared for testing. Multiple mutations may be introduced into individual restriction endonuclease genes. Targeted mutagenesis of restriction endonucleases may be achieved by any method known in the art. A convenient method used here is inverse PCR. In this approach, a pair of complementary primers that contains the targeted codon plus a plurality of nucleotides (for Example 18 nt) on both the 5′ and 3′ side of the codon is synthesized. The selection of suitable primers can be readily achieved by reviewing the gene sequence of the endonuclease of interest around the amino acid residue of interest. Access to gene sequences is provided through REBASE and GenBank. The template for PCR is a plasmid containing the restriction endonuclease gene. The polymerase is preferably a high fidelity polymerase such as Vent® or Deep Vent™ DNA polymerase. By varying the annealing temperature and Mg²⁺ concentration, successful introduction of most mutations can be achieved. The PCR amplification product is then purified and preferably digested by DpnI. In an embodiment of the invention, the digested product was transformed into competent host cells (for example, E. coli), which have been pre-modified with a corresponding methylase. Colonies from each mutant were picked and grown under similar conditions to those in which the WT is grown (for example, using similar growth medium, drug selection, and temperature). The resulting restriction endonucleases were screened for reduced star activity.

4. Screening for Mutant Restriction Endonucleases with Reduced Star Activity

Conditions such as buffer composition, temperature and diluent should be defined for determining star activity in a mutant restriction endonuclease. Tables 2 and 3 show the FI of recombinant endonucleases before and after mutation in four different buffers using three different diluents at 37° C. Accordingly, it is possible to determine which mutants have an overall desirable improved fidelity index factor of at least 2, more than 10, at least 50 or more than 500 and to select enzymes as preferred high fidelity mutants.

In an embodiment of the invention, the mutant restriction endonucleases were screened for activity in normal buffer conditions (no more than 5% glycerol) first. For those mutants with at least about 10% of activity of WT restriction endonuclease, activity was also determined in star activity promotion conditions that promoted star activity, for example, high glycerol concentration and optionally high pH. Preferably, the mutant with the least star activity but with acceptable cognate activity in normal buffers is selected. Plasmid can then be extracted and sequenced for the confirmation of the mutant. In some cases, the star activity is not easily measured, even with high glycerol and high pH conditions. Instead, the activity in different buffers is measured and compared, and the one with the highest cleavage activity ratio in NEB4 compared with NEB3 can be tested further for star activity improvement.

5. Saturation Mutagenesis on One Single Residue

As described in the previous section, the first step is to mutate a target amino acid in the restriction endonuclease to Ala. If the results are not satisfactory, saturation mutagenesis is performed. This is preferably performed by one of two methods. One method is to change the intended codon into NNN. After mutagenesis, multiple colonies are assayed under normal conditions and under conditions that promote star activity. Alternatively, a different codon can be selected for mutagenesis of each of the targeted amino acids for example: Ala: GCT; Cys: TGC; Asp: GAC; Glu: GAA; His: CAC; Ile: ATC; Lys: AAA; Leu: CTG; Met: ATG; Asn: AAC; Pro: CCG; Gln: CAG; Arg: CGT; Ser: TCC; Thr: ACC; Val: GTT; Trp: TGG and Tyr: TAC

6. Combination

More than one mutation can be introduced into the restriction endonuclease gene if a single mutation does not sufficiently reduce the star activity. Mutation combination and saturation mutagenesis can be performed in any order.

7. Mutant Purification and Assessment of the Improvement

The high fidelity mutants may be purified in a variety of ways including use of different chromatography columns. For normal quality assessment, one FPLC heparin column is enough to eliminate the DNA and non-specific nucleases from the preparation. Multiple columns including ion exchange, hydrophobic, size exclusion and affinity columns can be used for further purification.

Purified high fidelity restriction endonucleases are measured for FI in four NEB buffers and compared with the FIs of the WT restriction endonuclease. The ratio of FI for the high fidelity restriction endonuclease in its optimal buffer to that of WT is the overall improvement factor.

TABLE 3 FI* for exemplified restriction endonucleases Diluent Temp Enzyme (NEB) Substrate* ° C. FI-1** FI-2** FI-3** FI-4** AgeI-HF C pXba 37 ≧500 (1) ≧250 (½) ≧16 ( 1/16) ≧250 (1) AvrII-HF B T7 37 500 (1) ≧500 (½) ≧16 ( 1/64) ≧1000 (1) BamHI- A λ 37 ≧4000 (1) ≧4000 (1) ≧250 ( 1/16) ≧4000 (1) HF BsaI B pBC4 50 ≧4000 (½) ≧8000 (1) 120 (1) ≧8000 (1) BsmBI B λ 55 2 (1) ≧500 (1) ≧64 (⅛) ≧500 (1) BspQI-HF A pUC19 50 ≧1000 (¼) ≧1000 (¼) ≧64 ( 1/64) ≧4000 (1) BstXI-HF A λ 55 ≧120 (½) ≧250 (1) ≧16 ( 1/16) ≧250 (1) EagI-HF C pXba 37 250 (½) 250 (1) 250 (½) 500 (1) EcoRI-HF C λ 37 2000 (⅛) 4000 (¼) 250 ( 1/250) 16000 (1) EcoRV-HF A pXba 37 ≧16000 (¼) ≧64000 (1) ≧32000 (½) ≧64000 (1) HindIII- B λ 37 ≧16000 (¼) ≧64000 (1) ≧16000 (¼) ≧32000 (½) HF HpaI-HF A λ 37 ≧32 ( 1/32) ≧2000 (1) 2 (⅛) ≧2000 (½) KpnI-HF A pXba 37 ≧4000 (1) ≧1000 (¼) ≧64 ( 1/64) ≧4000 (1) MfeI-HF A λ 37 ≧1000 (1) ≧250 (¼) ≧16 ( 1/64) ≧500 (½) NcoI-HF A λ 37 ≧4000 (¼) ≧4000 (¼) ≧1000 ( 1/16) ≧64000 (1) NheI-HF C pXba 37 ≧128000 (1) ≧4000 ( 1/32) ≧32 (1/2000) ≧32000 (½) NotI-HF C pXba 37 ≧8000 ( 1/16) ≧128000 (1) ≧4000 ( 1/64) ≧64000 (½) PciI-HF A pXba 37 NC ≧2000 (1) ≧2000 (1) ≧1000 (1) PstI-HF C λ 37 1000 (⅛) 4000 (½) 4000 (¼) 4000 (1) PvuII-HF A pBR322 37 ≧250 ( 1/120) ≧2000 ( 1/16) ≧250 ( 1/120) 500 (1) SacI-HF A pXba 37 ≧32000 (1) ≧16000 (½) ≧500 ( 1/64) ≧32000 (1) SalI-HF A λ (H3) 37 ≧8000 (⅛) ≧64000 (1) ≧4000 ( 1/16) ≧32000 (½) SbfI-HF C λ 37 1000 (1) 120 (½) 8 ( 1/32) 250 (1) ScaI-HF A λ 37 4000 (⅛) 1000 (1) 2000 ( 1/32) 1000 (1) SphI-HF B λ 37 4000 (⅛) 2000 ( 1/16) 250 ( 1/250) 8000 (1) SspI-HF C λ 37 ≧4000 (½) 120 (½) ≧32 ( 1/128) 500 (1) *The FI is a ratio of the highest concentration that does not show star activity to the lowest concentration that completes digestion of the substrate. **The number in parenthesis is a value for relative cleavage activity of the mutant restriction endonuclease in a specified buffer in a set of buffers compared with the greatest cleavage activity of the same mutant restriction endonuclease in any of the buffers in the set of buffers.

TABLE 4 Mutations providing restriction endonucleases with high fidelity Restriction Endonuclease Examples of mutants with overall improved FI factor ≧ 2 AgeI R139A; S201A* AvrII Y104F; M29A; E96A; K106A; S127A; F142A BamHI E163A/E167T; K30A; E86A; E86P; K87A; K87E; K87V; K87N; P144A; Y165F; E167A; E167R; E167K; E167L; E167I K30A/E86A; E86A/K106A; K30A/E86A/K106A; K30A/K87A; E86P/K87E; E86A/Y165F; K30A/E167A; E163S/E170T/P173A; E163S/E170T/P173A; E86P/K87T/K88N/E163S/E170T/P173A; E86P/K87R/K88G/E163S/E170T/P173A;E86P/K87P/K88R/ E163S/E170T/P173A/E211K; E86P/K87T/K88R/ E163S/E170T/P173A/N158S; E86P/K87S/K88P/ E163S/E170T/P173A; E86P/K87G/K88S/E163S/E170T/P173A; E86P/K87R/K88Q/E163S/E170T/P173A; E86P/K87W/K88V; E86P/P173A BsaI Y231F BsmBI N185Y/R232A; H230A; D231A; R232A; BspQI K279P/R388F; K279A; K279F; K279P; K279Y; K279E; K279D R388A; R388F; R388Y; R388L; K279P/R388F; K279A/R388A; D244A BstXI N65A; Y57F; E75A; N76A; K199A; EagI H43A EcoRI K62A; K62S; K62L; R9A; K15A; R123A; K130A; R131A; R183A; S2Y; D135A; R187A; K62E EcoRV D19A; E27A; D19A/E27A HindIII S188P/E190A; K198A HpaI Y29F; E56A KpnI D148E; D16N/R119A/D148E; D2A/D16N/D148E; D16N/E134A/D148E; D16N/E132A/D148E MfeI Y173F; Q13A/F35Y NcoI D56A; H143A; E166A; R212A; D268A; A2T/R31A NheI E77A NotI K176A; R177A; R253A; K150A PciI E78A/S133A PstI E204G; K228A; K228A/A289V; D91A PvuII T46A; T46H; T46K; T46Y; T46G SacI Q117H/R154A/L284P; Q117H/R200A SalI R82A; K93A; K101A; R107A SapI K273P; R380A; K273P/R380A SbfI K251A ScaI R18A; R112A; E119A; H193A; S201F; H193A/S201F SphI D91A; D139A; D164A; K100A SspI H65A; K74A; E78A; E85A; E89A; K109A; E118A; R177A; K197A; Y98F The mutations for each enzyme are separated by a semicolon.

All references cited above and below, as well as U.S. Ser. No. 12/172,963 filed Jul. 14, 2008 and U.S. provisional application Ser. No. 60/959,203, are incorporated by reference.

EXAMPLES

Where amino acids are referred to by a single letter code, this is intended to be standard nomenclature. The key to the code is provided for example in the NEB catalog 2007/2008 on page 280.

Plasmids used for cloning and as substrates have sequences as follows:

pLaczz2 (SEQ ID NO:102), pSyx20-laclq (SEQ ID NO:105), pBC4 (SEQ ID NO:103), pXba (SEQ ID. NO:104) and pAGR3

(SEQ ID NO:106). pACYC is described in GenBank XO 6403, T7 in GenBank NC001604, pUC18 in GenBank L09136, and pRRS in Skoglund et al. Gene, 88:1-5 (1990. pSX33 was constructed by inserting lacI gene into pLG339 at EcoRI site. pLG339 is described in Stoker, et al. Gene 19, 335-341 (1982).

All buffers identified as NEB buffers used herein are obtainable from New England Biolabs, Inc. (NEB), Ipswich, Mass.

Example 1 Preparation of a High Fidelity EcoRI 1. Expression of EcoRI

PCR on EcoRI used the following primers:

(SEQ ID NO: 73) GGTGGTGCATGCGGAGGTAAATAAATGTCTAATAAAAAACAGTCAAATAG GCTA  (SEQ ID NO: 74) GGTGGTGGTACCTCACTTAGATCTAAGCTGTTCAAACAA

The PCR product was then digested with a second pair of restriction endonucleases—SphI and Acc65I, and ligated into the pUC19 digested with the same second pair of restriction endonucleases. The ligated plasmid was then be transformed into competent E. coli premodified with pACYC-MlucIM.

2. Mutagenesis of EcoRI

Initial selection of target amino acid residues resulted from a comparison of EcoRI with its isoschizomer RsrI, which is also known for its star activity.

EcoRI vs. RsrI    .   .   .   .     . 4 KKQSNRLTEQHKLSQGVIGIFGDYAKAHDLAVGEVSKLVKKALSNEYPQL 53 | |.|| | .| |:||| |.|||.:||. |  |.::| | 10 KGQALRLGIQQELGGGPLSIFGAAAQKHDLSIREVTAGVLTKLAEDFPNL 59    .    .   .    .    . 54 SFRYRDSIKKTEINEALKKIDPDLGGTLFVSNSSIKPDGGIVEVKDDYGE 103 |. | |: | ||| |: || || |||..||:||||| |||| :| 60 EFQLRTSLTKKAINEKLRSFDPRLGQALFVESASIRPDGGITEVKDRHGN 109   .   .   .   .    . 104 WRVVLVAEAKHQGKDIINIRNGLLVGKRGDQDLMAAGNAIERSHKNISEI 153 |||:|| |.|||| |: | |.| || ||| ||||||||| |||: |: 110 WRVILVGESKHQGNDVEKILAGVLQGKAKDQDFMAAGNAIERMHKNVLEL 159   .   .    .   .   . 154 ANFMLSESHFPYVLFLEGSNFLTENISITRPDGRVVNLEYNSGILNRLDR 203 |:|| | |||||.||:|||| ||. :|||||||| : :.||.|||:|| 160 RNYMLDEKHFPYVVFLQGSNFATESFEVTRPDGRVVKIVHDSGMLNRIDR 209   .   .   .    .   . 204 LTAANYGMPINSNLCINKFVNHKDKSIMLQAASIYTQGDGREWDSKIMFE 253 .||..  || | | | |   | | ||:|.  | . | | 210 VTASSLSREINQNYCENIVVRAGSFDHMFQIASLYCK..AAPWTAGEMAE 257   . 254 IMFDISTTSLRVLGRDL 270 (SEQ ID NO: 75) | :. ||||:: || 258 AMLAVAKTSLRIIADDL 274 (SEQ ID NO: 76)

Except for D91, E111 and K113, which were known active center residues, the 42 charged residues were identical or similar in the two endonucleases. The charged residues were as follows:

K4, R9, K15, K29, H31, D32, E37, E49, R56, R58, K63, E68, K71, D74, K89, E96, K98, K99, R105, H114, D118, K130, D133, D135, E144, R145, H147, K148, E152, E160, H162, E170, E177, R183, D185, R200, D202, R203, E253, R264, D269.

All of these charged residues were mutated to Ala (codon GCA, GCT, GCC or GCG) and the mutated genes amplified and cloned as follows:

The amplification mixture was the same as used in Example 1 of the parent application, U.S. Ser. No. 12/172,963 filed Jul. 14, 2008 (2 μl PCR primers each, 400 mM dNTP, 4 units of Deep Vent DNA polymerase, 10 μl 10× Thermopol buffer with additional 0, 2, 6 μl MgSO₄, and the total reaction volume was 100 μl) and was added to 1 μl pUC19-EcoRI).

The PCR reaction conditions was 94° C. for 5 minutes, followed by 25 cycles of 94° C. for 30 seconds, 55° C. for 30 seconds, 72° C. for 3 minutes and 30 seconds and a final extension time at 72° C. for 7 minutes. After PCR, the product was purified by the standard Qiagen spin column (Qiagen, Valencia, Calif.). 16 μl PCR product was digested by 20 units of DpnI for 1 hour. The digested product was transformed into a methylase protected competent E. coli preparation.

3. Screening EcoRI High Fidelity Mutants

Three colonies each were picked for each mutation and grown in LB with Ampicillin and Chloramphenicol for overnight. The activity assay was performed on pBR322 and lambda DNA to ensure the mutant had at least similar activity to WT EcoRI. Then these mutants were tested using 3 μl of cell extract in 2-fold serial dilution, 12 μl 50% glycerol, 3 μl of NEB1 buffer, 0.5 μl pBR322 and 11.5 μl water, reacted at 37° C. for one hour. However, none of the mutations improved the performance of star activity.

From this result, it was concluded that an effective mutation could not always be recognized as a homologous residue between isoschizomers.

4. Repeat Mutagenesis on the Rest of 32 Charged Residues

All remaining 32 charged residues were mutated into Ala as described in step 2 by targeting amino acid residues 5, 12, 14, 26, 40, 43, 44, 59, 62, 65, 72, 76, 100, 103, 117, 123, 131, 192, 221, 225, 226, 227, 228, 242, 244, 245, 247, 249, 257, 268, 272 and 277.

The numbers above correspond to amino acid positions in the EcoRI protein sequence (SEQ ID NO:83).

5. Repeat Selection

Four colonies were picked from each sample containing a different type of mutation and grown in 4 ml LB with CAM. After sonication, cell extracts were tested on lambda DNA substrate in normal glycerol condition in NEB1 buffer. Those extracts with similar activity were tested again on pUC19 substrate by adding 3 μl of cell extract in two-fold serial dilutions, in 3 μl of NEB2 buffer to 0.5 μl of pUC19 and 23.5 μl 50% glycerol to provide a final concentration of 39.2% glycerol in the reaction mixture.

Among all of these mutants, K62A was found to be the mutation with the least star activity and a high FI. R9A, K15A, R123A, K130A, R131A, R183A mutants all showed partial reduction in star activity. Interestingly, one clone containing the targeted mutation K5A showed a partial improvement. Additionally, a secondary mutation, S2Y was found after sequencing. Separation of these two mutations revealed that the effective mutation for this isolate was S2Y. D135A and R187A EcoRI also had much less star activity. However, the cleavage activity of these mutants was not optimal.

6. Comparison of EcoRI(K62A) with WT EcoRI

A side-by-side comparison was performed in a 3-fold serial dilution using NEB dilution buffer C, by digesting 0.6 μg of lambda DNA in four different NEB buffers (FIG. 2A-D). EcoRI(K62A) had substantially less star activity than the WT EcoRI.

A more quantitative comparison was done by determining the Fidelity Index measurement for EcoRI(K62A) and WT EcoRI. The conditions for the fidelity index measurement was the same as for Table 2 using lambda DNA as substrate and, dilution buffer C. The reaction was incubated at 37° C. for 1 hour and the digestion products analyzed on an 0.8% agarose gel.

TABLE 7 Fidelity Index for EcoRI(K62A) and WT EcoRI EcoRI(K62A) WT EcoRI Fidelity Fidelity Improvement Buffer Activity Index Activity Index Factor NEB1  50% 32000  50% 250 128 NEB2  50% 8000 100% 4 2000 NEB3 12.5% 4000 100% 250 16 NEB4  100% 32000 100% 4 8000 EcoRI 12.5% 4000 100% 250 16 buffer

7. Further Mutation of EcoRI

Though it was not apparent that the EcoRI(K62A) had star activity on lambda DNA substrate, star activity was observed using Litmus28 substrate after a 10 hours digestion. EcoRI(K62A) in NEB4 had significantly reduced star activity compared with WT EcoRI in EcoRI buffer (FIG. 3A-C).

Further improvements were investigated. EcoRI(K62) was mutated to all other amino acid residues by changing K to the corresponding codons as in the example 1. K62S and K62L were similar as K62A. EcoRI(K62E) had a ≧100 fold overall fidelity index improvement factor when compared with EcoRI(K62A) as shown in FIG. 2A-D. EcoRI(K62E) was named EcoRI-HF.

8. Comparison of EcoRI-HF and WT EcoRI

A quantitative comparison was done by the FI measurement on EcoRI-HF and WT EcoRI in diluent C. The conditions for the FI measurement were the same as in Table 2 using lambda DNA as substrate. The reaction conditions were 37° C. for 1 hour and the results analyzed on a 0.8% agarose gel (FIG. 4A-B).

TABLE 8 Comparison of EcoRI-HF and WT EcoRI EcoRI-HF WT EcoRI Fidelity Fidelity Improvement Buffer Activity Index Activity Index Factor NEB1 12.5%  2000  50% 250 8 NEB2 100% 4000 100% 4 1000 NEB3  0.4% 250 100% 250 1 NEB4 100% 16000 100% 4 4000 EcoRI  0.4% 250 100% 250 1 buffer

The overall fidelity index improvement factor was found to be 64 fold (16000 in NEB4 for EcoRI-HF to 250 of WT EcoRI in NEB3). 

What is claimed is: 1.-18. (canceled)
 19. A screening method comprising: i. identifying which amino acid residues in an amino acid sequence of a restriction endonuclease having star activity are charged amino acids; ii. mutating one or more codons encoding one or more of the charged residues in a gene sequence encoding the restriction endonuclease; iii. generating a library of gene sequences having one or more different codon mutations in different charged residues; iv. obtaining a set of proteins expressed by the mutated gene sequences; and v. determining a cleavage activity for each protein, and determining a fidelity index for each protein in a predetermined buffer, wherein determining a fidelity index comprises determining the ratio of the highest concentration of protein that does not show star activity to the lowest concentration of protein that completes digestion of the substrate.
 20. A method according to claim 19, further comprising: i. determining an overall fidelity index improvement factor for proteins belonging to the set of proteins in a defined set of buffers; and/or ii. mutating codons encoding hydroxylated amino acids, in a same or subsequent step to that of mutating codons for the charged amino acids; and/or iii. mutating codons encoding amide-containing amino acids, in a same or subsequent step to that of mutating codons for the charged amino acids; and/or iv. improving the overall fidelity index improvement factor using saturation mutagenesis of one or more of the mutated codons.
 21. A method according to claim 19, wherein the codons are mutated to an alanine, except for tyrosine which is mutated to a phenylalanine.
 22. A method according to claim 20, wherein the codons are mutated to an alanine, except for tyrosine which is mutated to a phenylalanine. 